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Observational Astronomy - Lecture 5The Motion of the Earth and Moon
Time, Precession, Eclipses, Tides
Craig Lage
New York University - Department of Physics
March 2, 2014
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Geosynchronous Orbits
Moon
LEO
Geosynchronous
Not to scale.
Objects in Low Earth Orbit (LEO)circle the Earth in about 90 minutes.
The moon circles the Earth in 27.3days (about 655 hours).
At the right distance (about R =42000 km), a satellite will circle theEarth in one sidereal day (23h 56m).
These satellites stay fixed in the sky.
Sheet1
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Planet a(km) T(Hr)LEO 6700 1.53 1.29Moon 381000 655.20 1.29GEO 42000 23.93 1.29
a3/T2 (1E11 km^3/hr^2)
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Solar Time vs Sidereal Time
23h 56m 4s
3m 56s
The time from one noon to thenext is called a solar day
The time from one star transitto the next is called a siderealday
A sidereal day is 4 minutes less(actually 3 minutes 56 seconds)less than a solar day.
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Origin of Solar Day
One solar day = 23h56m4s + 3m56s.
The 23h56m4s is the time it takes theEarth to rotate on its axis.
This time is very accurately constant -within microseconds per day.
The 3m56s varies through the year,because the Earth’s speed in its orbitvaries due to Kepler’s second law.
We define the Mean Solar Day as theaverage of this quantity through theyear.
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Equation of time
There are two effects - variation inspeed due to elliptical orbit.
Variation in speed due to inclination ofEarth’s axis.
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Why our calendar works as it does.
Measurements tell us there are 365.2425 mean solar days in a year.
Early calendars had 365 days in a year.
The Julian calendar (45 BC), added an extra day every 4 years.
This calendar has 365.25 days per year.It loses one day every 133 years (1 / .0075).
By the middle ages, the Julian calendar had drifted ≈ 10 daysrelative to the sun.
Pope Gregory, in 1582, proposed the adoption of the Gregoriancalendar, which we use today.
This calendar works as follows:
365 days in a normal year = 365.0000Add a day every 4 years = 365.2500Skip the leap year if the year is divisible by 100 = 365.2400Add it back in if it is divisible by 400 = 365.2425
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The Julian day
Our calendar is complicated - calculating the difference between twodates is hard.
Astronomers (and computer programmers!) use the concept ofJulian Day.
This is a sequential counting of days starting on January 1, 4713 BC.
Today (March 3, 2014) is Julian Day 2,456,719.
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Precession
Precession causes the equatorial coordinate system to move.One complete circle takes 26,000 years.
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How much do the coordinates change?
Example - Aldebaran - α Tauri.
B1950 : Dec = +43 30’ RA = 16h25m
J2000 : Dec = +43 59’ RA = 16h31m
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Physics of precession
The top precesses because ofgravity.
The Earth precesses because of thegravitational pull of the sun and moon on
the Earth’s equatorial bulge.
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Eclipse cycles - the SarosSheet1
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Month Length Number TimeSidereal Stellar position 27.321661
Perigee-Perigee 27.554551 717 19756.613067Node-Node 27.212220 726 19756.071720Phase-Phase 29.530587 669 19755.962703
Year 365.2425 54.0954 years 32.9 days
AnomalisticDraconicSynodic
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Tidal locking and resonances
Tides dissipate energy, and lead to “tidal locking” of orbiting bodies.
Best known example - the moon, whose rotation rate is tidally lockedto its orbital period.
Tides are slowing down the Earth’s rotation:
Eventually (billions of years in the future) the Earth and moon will“co-rotate”, each showing the same face to the other.
There are many examples of tidal locking known, in our solar systemand in other systems:
Mercury is locked in a 3:2 resonance - 3 sidereal days equals 2 years,or 1 solar day equals 2 years.Jupiter’s three largest moons are locked in a 1:2:4 resonance.There are many more examples.
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